Led/oled array approach to integrated display, lensless-camera, and touch-screen user interface devices and associated processors

ABSTRACT

A system for implementing a display which also serves as one or more of a tactile user interface touchscreen, light field sensor, proximate hand gesture sensor, and lensless imaging camera. In an implementation, an OLED array can be used for light sensing as well as light emission functions. In one implementation a single OLED array is used as the only optoelectronic user interface element in the system. In another implementation two OLED arrays are used, each performing and/or optimized from different functions. In another implementation, an LCD and an OLED array are used in various configurations. The resulting arrangements allow for sharing of both optoelectric devices as well as associated electronics and computational processors, and are accordingly advantageous for use in handheld devices such as cellphone, smartphones, PDAs, tablet computers, and other such devices.

CROSS-REFERENCE TO RELATED APPLICATIONS

Pursuant to 35 U.S.C. §119(e), this application claims benefit of priority from Provisional U.S. Patent application Ser. No. 61/363,181, filed Jul. 9, 2010, the contents of which are incorporated by reference.

COPYRIGHT & TRADEMARK NOTICES

Certain marks referenced herein may be common law or registered trademarks of the applicant, the assignee or third parties affiliated or unaffiliated with the applicant or the assignee. Use of these marks is for providing an enabling disclosure by way of example and shall not be construed to exclusively limit the scope of the disclosed subject matter to material associated with such marks.

BACKGROUND OF THE INVENTION

Throughout the discussion, although “OLED” is in places called out specifically, an “Organic Light Emitting Diode” (OLED) is regarded as a type of “Light Emitting Diode” (LED). The term “inorganic-LED” is used to specifically signify traditional LEDs made of non-organic materials such as silicon, indium-phosphide, etc. FIG. 1 depicts a visual classification representation showing inorganic-LEDs and Organic Light Emitting Diodes (OLEDs) as mutually-exclusive types of Light Emitting Diodes (LEDs).

Color inorganic-LED array displays are currently employed in “LED TV” products and road-side and arena color-image LED advertising signs.

Color OLED array displays have begun to appear in cellphones, smartphones, and Personal Digital Assistants (“PDAs”) manufactured by Samsung, Nokia, LG, HTC, Phillips, Sony and others. Color OLED array displays are of particular interest, in general and as pertaining to the present invention, because:

-   -   They can be fabricated (along with associated electrical wiring         conductors) via printed electronics on a wide variety of         surfaces such as glass, Mylar, plastics, paper, etc.;     -   Leveraging some such surface materials, they can be readily         bent, printed on curved surfaces, etc.;     -   They can be transparent (and be interconnected with transparent         conductors);     -   Leveraging such transparency, they can be:         -   Stacked vertically,         -   Used as an overlay element atop an LCD or other display,         -   Used as an underlay element between an LCD and its             associated backlight.

LEDs as Light Sensors

Light detection is typically performed by photosite CCD (charge-coupled device) elements, phototransistors, CMOS photodetectors, and photodiodes. Photodiodes are often viewed as the simplest and most primitive of these, and typically comprise a PIN (P-type/Intrinstic/N-type) junction rather than the more abrupt PIN (P-type/N-type) junction of conventional signal and rectifying diodes.

However, virtually all diodes are capable of photovoltaic properties to some extent. In particular, LEDs, which are diodes that have been structured and doped specific types of optimized light emission, can also behave as (at least low-to moderate performance) photodiodes. In popular circles Forrest M. Mims has often been credited as calling attention to the fact that that a conventional LED can be used as a photovoltaic light detector as well as a light emitter (Mims III, Forrest M. “Sun Photometer with Light-emitting diodes as spectrally selective detectors” Applied Optics, Vol. 31, No. 33, Nov. 20, 1992), and as a photodetector LEDs exhibit spectral selectivity associated with the LED's emission wavelength. More generally, inorganic-LEDs, organic LEDs (“OLEDs”), organic field effect transistors, and other related devices exhibit a range of readily measurable photo-responsive electrical properties, such as photocurrents and related photovoltages and accumulations of charge in the junction capacitance of the LED.

Further, the relation between the spectral detection band and the spectral emission bands of each of a plurality of colors and types of color inorganic-LEDs, OLEDs, and related devices can be used to create a color light-field sensor from, for example, a color inorganic-LED, OLED, and related device array display. Such arrangements have been described in pending U.S. patent application Ser. No. 12/419,229 (priority date Jan. 27, 1999), pending U.S. patent application Ser. No. 12/471,275 (priority date May 25, 2008), and in pending U.S. patent application Ser. Nos. 13/072,588 and 61/517,454. The present invention expands further upon this.

Pending U.S. patent application Ser. Nos. 12/419,229 (priority date Jan. 27, 1999), 12/471,275 (priority date May 25, 2008), 13/072,588, and 61/517,454 additionally teaches how such a light-field sensor can be used together with signal processing software to create lensless-imaging camera technology, and how such technology can be used to create an integrated camera/display device which can be used, for example, to deliver precise eye-contact in video conferencing applications.

In an embodiment provided for by the invention, each LED in an array of LEDs can be alternately used as a photodetector or as a light emitter. At any one time, each individual LED would be in one of three states:

-   -   A light emission state,     -   A light detection state,     -   An idle state.         as may be advantageous for various operating strategies. The         state transitions of each LED may be coordinated in a wide         variety of ways to afford various multiplexing, signal         distribution, and signal gathering schemes as may be         advantageous.

Leveraging this in various ways, in accordance with embodiments of the invention, array of inorganic-LEDs, OLEDs, or related optoelectronic devices is configured to perform functions of two or more of:

-   -   a visual image display (graphics, image, video, GUI, etc.),     -   a (lensless imaging) camera,     -   a tactile user interface (touch screen),     -   a proximate gesture user interface.

These arrangements further advantageously allow for a common processor to be used for two or more display, user interface, and camera functionalities.

The result dramatically decreases the component count, system hardware complexity, and inter-chip communications complexity for contemporary and future mobile devices such as cellphones, smartphones, PDAs, tablet computers, and other such devices.

In cases where a user interface is incorporated, the RF capacitive matrix arrangements used in contemporary multi-touch touchscreen are replaced with an optical interface.

Further, the integrated camera/display operation removes the need for a screen-direction camera and interface electronics in mobile devices. The integrated camera/display operation can also improve eye contact in mobile devices.

SUMMARY OF THE INVENTION

For purposes of summarizing, certain aspects, advantages, and novel features are described herein. Not all such advantages may be achieved in accordance with any one particular embodiment. Thus, the disclosed subject matter may be embodied or carried out in a manner that achieves or optimizes one advantage or group of advantages without achieving all advantages as may be taught or suggested herein.

In accordance with embodiments of the invention, a system is taught for implementing a display which also serves as one or more of a tactile user interface touchscreen, light field sensor, proximate hand gesture sensor, and lensless imaging camera. In an implementation, an OLED array can be used for light sensing as well as light emission functions. In one implementation a single OLED array is used as the only optoelectronic user interface element in the system. In another implementation two OLED arrays are used, each performing and/or optimized from different functions. In another implementation, an LCD and an OLED array are used in various configurations. The resulting arrangements allow for sharing of both optoelectric devices as well as associated electronics and computational processors, and are accordingly advantageous for use in handheld devices such as cellphone, smartphones, PDAs, tablet computers, and other such devices.

In accordance with embodiments of the invention, array of inorganic-LEDs, OLEDs, or related optoelectronic devices is configured to perform functions of a display, a camera, and a hand-operated user interface sensor.

In an embodiment, an array of inorganic-LEDs, OLEDs, or related devices, together with associated signal processing aspects of the invention, can be used to implement a tactile user interface.

In an embodiment, an array of inorganic-LEDs, OLEDs, or related devices, together with associated signal processing aspects of the invention, can be adapted to function as both an image display and light-field sensor which can be used to implement a proximate image user interface.

In an embodiment, an array of inorganic-LEDs, OLEDs, or related devices, together with associated signal processing aspects of the invention, can be adapted to function as both an image display and light-field sensor which can be used to implement a tactile user interface sensor.

In an embodiment, an array of inorganic-LEDs, OLEDs, or related devices, together with associated signal processing aspects of the invention, can be adapted to function as both an image display and light-field sensor which can be used to implement a proximate image user interface sensor.

In an embodiment, an array of inorganic-LEDs, OLEDs, or related devices, together with associated signal processing aspects of the invention, can be adapted to function as both an image display and light-field sensor which can be used to implement a tactile user interface (touch screen), lensless imaging camera, and visual image display.

In an embodiment, an array of inorganic-LEDs, OLEDs, or related devices, together with associated signal processing aspects of the invention, can be adapted to function as both an image display and light-field sensor which can be used to implement a proximate gesture user interface, lensless imaging camera, and visual image display.

In an embodiment, an array of inorganic-LEDs, OLEDs, or related devices, together with associated signal processing aspects of the invention, can be adapted to function as both an image display and light-field sensor which can be used to implement a proximate gesture user interface, tactile user interface (touch screen), lensless imaging camera, and visual image display.

In accordance with embodiments of the invention, a system for implementing the function of a visual display, light field sensor, and a user interface for operated by a user hand is taught, the system comprising:

-   -   A processor, the processor having an electrical interface and         for executing at least one software algorithm;     -   A transparent OLED array comprising at least a plurality of         OLEDs, the OLED array configured to be in communication with the         electrical interface of the processor;     -   An optical vignetting arrangement for providing a plurality of         distinct vignets of an incoming light field, and     -   A light emitting arrangement associated with the transparent         OLED array, the light emitting arrangement for providing a         visual display;     -   Wherein each distinct vignet of the incoming light field is         directed to an associated individual OLED from the plurality of         OLEDs;     -   Wherein each of the individual OLED performs a light detection         function at least for an interval of time, the light detection         function comprising a photoelectric effect that is communicated         to the processor via the electrical interface of the processor;         and     -   Wherein the photoelectric effect that is communicated to the         processor is used to obtain light field measurement information         responsive to the incoming light field.

BRIEF DESCRIPTION OF THE DRAWINGS

The above and other aspects, features and advantages of the present invention will become more apparent upon consideration of the following description of preferred embodiments taken in conjunction with the accompanying drawing figures, wherein:

FIG. 1 depicts a visual classification representation showing inorganic-LEDs and Organic Light Emitting Diodes (OLEDs) as mutually-exclusive types of Light Emitting Diodes (LEDs).

FIG. 2 depicts a representation of the spread of electron energy levels as a function of the number of associated electrons in a system such as a lattice of semiconducting material resultant from quantum state exclusion processes. (The relative positions vertically and from column-to-column are schematic and not to scale, and electron pairing effects are not accurately represented.)

FIG. 3 depicts an example electron energy distribution for metals, (wherein the filled valance band overlaps with the conduction band).

FIG. 4 depicts an example electron energy distribution for semiconductors (wherein the filled valance band is separated from the conduction band by a gap in energy values; this gap is the “band gap”).

FIG. 5 depicts an exemplary (albeit not comprehensive) schematic representation of the relationships between valance bands and conduction bands in materials distinctly classified as metals, semiconductors, and insulators. (Adapted from Pieter Kuiper, http://en.wikipedia.org/wiki/Electronic_band_structure, visited Mar. 22, 2011.)

FIG. 6 depicts the how the energy distribution of electrons in the valance band and conduction band vary as a function of the density of electron states, and the resultant growth of the band gap as the density of electron states increases. (Adapted from Pieter Kuiper, http://en.wikipedia.org/wiki/Band_gap, visited Mar. 22, 2011.)

FIG. 7 depicts three exemplary types of electron-hole creation processes resulting from absorbed photons that contribute to current flow in a PN diode (adapted from A. Yariv, Optical Electronics, 4th edition, Saunders College Press, 1991, p. 423).

FIG. 8 depicts exemplary electron energy distribution among bonding and antibonding molecular orbitals in conjugated or aromatic organic compounds (adapted from Y. Divayana, X. Sung, Electroluminescence in Organic Light-Emitting Diodes, VDM Verlag Dr. Müller, Saarbrücken, 2009, ISBN 978-3-639-17790-9, FIG. 2.2, p. 13).

FIG. 9 depicts an optimization space for semiconductor diodes comprising attributes of signal switching performance, light emitting performance, and light detection performance.

FIG. 10 depicts an exemplary metric space of device realizations for optoelectronic devices and regions of optimization and co-optimization.

FIGS. 11-14 depict various exemplary circuits demonstrating various exemplary approaches to detecting light with an LED.

FIG. 15 depicts a selectable grounding capability for a two-dimensional array of LEDs.

FIG. 16 depicts an adaptation of the arrangement depicted in FIG. 15 that is controlled by an address decoder so that the selected subset can be associated with a unique binary address.

FIG. 17 depicts an exemplary highly-scalable electrically-multiplexed LED array display that also functions as a light field detector.

FIGS. 18 and 19 depict exemplary functional cells that may be used in a large scale array.

FIGS. 20-22 depict adaptations of the digital circuit measurement and display arrangements into an example combination.

FIGS. 23-26 depict exemplary state diagrams for the operation of the LED and the use of input signals and output signals.

FIG. 27 depicts an exemplary high-level structure of a three-color transparent Stacked OLED (“SOLED”) element as can be used for color light emission, color light sensing, or both. (Adapted from G. Gu, G. Parthasarathy, P. Burrows, T. Tian, I. Hill, A. Kahn, S. Forrest, “Transparent stacked organic light emitting devices. I. Design principles and transparent compound electrodes,” Journal of Applied Physics, October 1999, vol. 86 no. 8, pp. 4067-4075.)

FIG. 28 depicts a conventional “RGB stripe” OLED array as used in a variety of OLED display products and as can be used for light field sensing in accordance with aspects of the present invention. (Adapted from http://www.displayblog.com/2009/03/26/samsung-oled-pentile-matrix-next-iphone-oled-display/ (visited Mar. 23, 2011.)

FIG. 29 depicts a representation of the “PenTile Matrix” OLED array as attributed to Samsung and as can be used for light field sensing in accordance with aspects of the present invention. (Adapted from http://www.displayblog.com/2009/03/26/samsung-oled-pentile-matrix-next-iphone-oled-display/ (visited Mar. 23, 2011.)

FIG. 30 depicts an exemplary embodiment comprising an LED array preceded by a vigneting arrangement as is useful for implementing a lensless imaging camera as taught in U.S. patent application Ser. Nos. 12/419,229 (priority date Jan. 27, 1999), 12/471,275 (priority date May 25, 2008), 13/072,588, and 61/517,454.

FIG. 31 depicts an exemplary implementation comprising a transparent OLED array overlaid upon an LCD display, which is in turn overlaid on a (typically) LED backlight used to create and direct light though the LCD display from behind.

FIG. 32 depicts an exemplary implementation comprising a first transparent OLED array used for at least optical sensing overlaid upon a second OLED array used for at least visual display.

FIG. 33 depicts an exemplary implementation comprising a first transparent OLED array used for at least visual display overlaid upon a second OLED array used for at least optical sensing.

FIG. 34 depicts an exemplary implementation comprising an LCD display, used for at least visual display and vignette formation, overlaid upon a second LED array, used for at least backlighting of the LCD and optical sensing.

FIG. 35 an exemplary arrangement employed in contemporary cellphones, smartphones, PDAs, tablet computers, and other portable devices wherein a transparent capacitive matrix proximity sensor is overlaid over an LCD display, which is in turn overlaid on a (typically LED) backlight used to create and direct light though the LCD display from behind. Each of the capacitive matrix and the LCD have considerable associated electronic circuitry and software associated with them.

FIG. 36 depicts an exemplary modification of the arrangement depicted in FIG. 35 wherein the LCD display and backlight are replaced with an OLED array used as a visual display. Such an arrangement has started to be incorporated in recent contemporary cellphone, smartphone, PDA, tablet computers, and other portable device products by several manufacturers.

FIG. 37 depicts an exemplary arrangement provided for by the invention comprising only a LED array. The LEDs in the LED array may be OLEDs or inorganic LEDs. Such an arrangement can be used as a visual display and as a tactile user interface.

FIG. 38 depicts a representative exemplary arrangement wherein light emitted by neighboring LEDs is reflected from a finger back to an LED acting as a light sensor.

FIG. 39 depicts an exemplary arrangement wherein a particular LED designated to act as a light sensor is surrounded by immediately-neighboring LEDs designated to emit light to illuminate the finger for example as depicted in FIG. 38.

FIG. 40 depicts an exemplary arrangement wherein a particular LED designated to act as a light sensor is surrounded by immediately-neighboring LEDs designated to serve as a “guard” area, for example not emitting light, these in turn surrounded by immediately-neighboring LEDs designated to emit light used to illuminate the finger for example as depicted in FIG. 38.

FIG. 41 depicts an exemplary reference arrangement comprised by mobile devices such as cellphones, smartphones, PDAs, tablet computers, and other such devices.

FIG. 42 depicts an exemplary variation of the exemplary reference arrangement of FIG. 41 wherein an LED array replaces the display, camera, and touch sensor and is interfaced by a common processor that replaces associated support hardware.

FIG. 43 depicts an exemplary variation of the exemplary reference arrangement of FIG. 42 wherein the common processor associated with the LED array further executes at least some touch-based user interface software.

FIG. 44 depicts an exemplary variation of the exemplary reference arrangement of FIG. 42 wherein the common processor associated with the LED array further executes all touch-based user interface software.

FIG. 45 depicts an exemplary embodiment comprising an LED array preceded by a micro optics array and a capacitive matrix sensor

FIG. 46 depicts an exemplary embodiment comprising an LED array preceded by a micro optics array configured to also function as a capacitive matrix sensor.

DETAILED DESCRIPTION

The above and other aspects, features and advantages of the present invention will become more apparent upon consideration of the following description of preferred embodiments taken in conjunction with the accompanying drawing figures.

In the following description, reference is made to the accompanying drawing figures which form a part hereof, and which show by way of illustration specific embodiments of the invention. It is to be understood by those of ordinary skill in this technological field that other embodiments may be utilized, and structural, electrical, as well as procedural changes may be made without departing from the scope of the present invention.

Inorganic and Organic Semiconductors

FIG. 2 depicts a representation of the spread of electron energy levels as a function of the number of associated electrons in a system such as a lattice of semiconducting material resultant from quantum state exclusion processes. As the number of associated electrons in a system increases, the separation between consecutive energy levels decreases, in the limit becoming an effective continuum of energy levels. Higher energy level electrons form a conduction band while lower energy electrons lie in a valence band. The relative positions vertically and from column-to-column are schematic and not to scale, and electron pairing effects are not accurately represented.

FIG. 3 depicts an example electron energy distribution for metals, (wherein the filled valance band overlaps with the conduction band).

FIG. 4 depicts an example electron energy distribution for semiconductors; here the filled valance band is separated from the conduction band by a gap in energy values. The “band gap” is the difference in energy between electrons at the top of the valence band and electrons at the bottom of the conduction band. For a semiconductor the band gap is small, and manipulations of materials, physical configurations, charge and potential differences, photon absorption, etc. can be used to move electrons through the band gap or along the conduction band.

Elaborating further, FIG. 5 (adapted from Pieter Kuiper, http://en.wikipedia.org/wiki/Electronic_band_structure, visited Mar. 22, 2011) depicts an exemplary (albeit not comprehensive) schematic representation of the relationships between valance bands and conduction bands in materials distinctly classified as metals, semiconductors, and insulators. The band gap is a major factor determining the electrical conductivity of a material. Although metal conductor materials are shown having overlapping valance and conduction bands, there are some conductors that instead have very small band gaps. Materials with somewhat larger band gaps are electrical semiconductors, while materials with very large band gaps are electrical insulators.

The affairs shown in FIG. 1 and FIG. 4 are related. FIG. 6 (adapted from Pieter Kuiper, http://en.wikipedia.org/wiki/Band_gap, visited Mar. 22, 2011) depicts how the energy distribution of electrons in the valance band and conduction band vary as a function of the density of assumed electron states per unit of energy, illustrating growth of the size of the band gap as the density of states (horizontal axis) increases.

Light Sensing by Photodiodes and LEDs

Electrons can move between the valence band and the conduction band by means of special processes that give rise to hole-electron generation and hole-electron recombination. Several such processes are related to the absorption and emission of photons which make up light.

Light detection in information systems is typically performed by photosite CCD (charge-coupled device) elements, phototransistors, CMOS photodetectors, and photodiodes. By way of example, FIG. 7 (adapted from A. Yariv, Optical Electronics, 4th edition, Saunders College Press, 1991, p. 423) depicts three exemplary types of electron-hole creation processes resulting from absorbed photons that contribute to current flow in a PN diode. Emitted photons cause electrons to drop through the band gap while absorbed photons of sufficient energy can excite electrons from the valance band though the band gap to the conduction band.

Photodiodes are often viewed as the simplest and most primitive form of semiconductor light detector. A photodiode typically comprises a PIN (P-type/Intrinsic/N-type) junction rather than the more abrupt PIN (P-type/N-type) junction of conventional signal and rectifying diodes. However, photoelectric effects and capabilities are hardly restricted to PIN diode structures. In varying degrees, virtually all diodes are capable of photovoltaic properties to some extent.

In particular, LEDs, which are diodes that have been structured and doped for specific types of optimized light emission, can also behave as (at least low-to-medium performance) photodiodes. Additionally, LEDs also exhibit other readily measurable photo-responsive electrical properties, such as photodiode-type photocurrents and related accumulations of charge in the junction capacitance of the LED. In popular circles Forrest M. Mims has often been credited as calling attention to the fact that that a conventional LED can be used as a photovoltaic light detector as well as a light emitter (Mims III, Forrest M. “Sun Photometer with Light-emitting diodes as spectrally selective detectors” Applied Optics, Vol. 31, No. 33, Nov. 20, 1992). More generally LEDs, organic LEDs (“OLEDs”), organic field effect transistors, and other related devices exhibit a range of readily measurable photo-responsive electrical properties, such as photocurrents and related photovoltages and accumulations of charge in the junction capacitance of the LED.

In an LED, light is emitted when holes and carriers recombine and the photons emitted have an energy in a small range either side of the energy span of the band gap. Through engineering of the band gap, the wavelength of light emitted by an LED can be controlled. In the aforementioned article, Mims additionally pointed out that as a photodetector LEDs exhibit spectral selectivity with at a light absorption wavelength similar to that of the LED's emission wavelength. More details as to the spectral selectivity of the photoelectric response of an LED will be provided later.

Attention is now directed to organic semiconductors and their electrical and optoelectrical behavior. Conjugated organic compounds comprise alternating single and double bonds in the local molecular topology comprising at least some individual atoms (usually carbon, but can be other types of atoms) in the molecule. The resulting electric fields organize the orbitals of those atoms into a hybrid formation comprising a σ bond (which engage electrons in forming the molecular structure among joined molecules) and a π cloud of loosely associated electrons that are in fact delocalized and can move more freely within the molecule. These delocalized π electrons provide a means for charge transport within the molecule and electric current within larger-structures of organic materials (for example, polymers).

Combinations of atomic orbital modalities for the individual atoms in a molecule, together with the molecular topology (created by the σ bonds) and molecular geometry, create molecule-scale orbitals for the delocalized π cloud of electrons and in a sense for the electrons comprising σ bonds. Interactions among the electrons, in particular quantum exclusion processes, create an energy gap between the Highest Occupied Molecular Orbital (“HOMO”) and Lowest-Unoccupied Molecular Orbital (“LUMO”) for the delocalized π electrons (and similarly does so for the more highly localized σ bond electrons). FIG. 8 (adapted from Y. Divayana, X. Sung, Electroluminescence in Organic Light-Emitting Diodes, VDM Verlag Dr. Müller, Saarbrücken, 2009, ISBN 978-3-639-17790-9, FIG. 2.2, p. 13) depicts the electron energy distribution among bonding (π and σ) and antibonding (π* and σ*) molecular orbitals in for two electrons in an exemplary conjugated or aromatic organic compound. In such materials typically the energy gap between the π and π* molecular orbitals correspond to the gap between the HOMO and LUMO. The HOMO effectively acts as a valence band in a traditional (inorganic) crystal lattice semiconductor and the LUMO acts as effective equivalent to a conduction band. Accordingly, energy gap between the HOMO and LUMO (usually corresponding to the gap between the π and π* molecular orbitals) behaves in a manner similar to the band gap in a crystal lattice semiconductor and thus permits many aromatic organic compounds to serve as electrical semiconductors.

Emitted photons cause electrons to drop through the HOMO/LUMO gap while absorbed photons of sufficient energy can excite electrons from the HOMO to the LUMO. These processes are similar to photon emission and photo absorption processes in a crystal lattice semiconductor and can be used to implement organic LED (“OLED”) and organic photodiode effects with aromatic organic compounds. Functional groups and other factors can vary the width of the band gap so that it matches energy transitions associated with selected colors of visual light. Additional details on organic LED (“OLED”) processes, materials, operation, fabrication, performance, and applications can be found in, for example:

-   Z. Li, H. Ming (eds.), Organic Light-Emitting Materials and Devices,     CRC Taylor & Francis, Boca Raton, 2007, ISBN 1-57444-574-X; -   Z. Kafafi (ed.), Organic Electroluminescence, CRC Taylor & Francis,     Boca Raton, 2005, ISBN 0-8247-5906-0; -   Y. Divayana, X. Sung, Electroluminescence in Organic Light-Emitting     Diodes, VDM Verlag Dr. Müller, Saarbrücken, 2009, ISBN     978-3-639-17790-9.

It is noted that an emerging alternative to OLEDs are Organic Light Emitting Transistors (OLETS). The present invention allows for arrangements employing OLETS to be employed in place of OLEDs and LEDs as appropriate and advantageous wherever mentioned throughout the specification.

Potential Co-Optimization of Light Sensing and Light Emitting Capabilities of an Optical Diode Element

FIG. 9 depicts an optimization space 200 for semiconductor (traditional crystal lattice or organic material) diodes comprising attributes of signal switching performance, light emitting performance, and light detection performance. Specific diode materials, diode structure, and diode fabrication approaches 223 can be adjusted to optimize a resultant diode for switching function performance 201 (for example, via use of abrupt junctions), light detection performance 202 (for example via a P-I-N structure comprising a layer of intrinsic semiconducting material between regions of n-type and p-type material, or light detection performance 203.

FIG. 10 depicts an exemplary metric space 1900 of device realizations for optoelectronic devices and regions of optimization and co-optimization.

Specific optoelectrical diode materials, structure, and fabrication approaches 1923 can be adjusted to optimize a resultant optoelectrical diode for light detection performance 1901 (for example via a P-I-N structure comprising a layer of intrinsic semiconducting material between regions of n-type and p-type material versus light emission performance 1902 versus cost 1903. Optimization within the plane defined by light detection performance 1901 and cost 1903 traditionally result in photodiodes 1911 while optimization within the plane defined by light emission performance 1902 and cost 1903 traditionally result in LEDs 1912. The present invention provides for specific optoelectrical diode materials, structure, and fabrication approaches 1923 to be adjusted to co-optimize an optoelectrical diode for both good light detection performance 1901 and light emission performance 1902 versus cost 1903. A resulting co-optimized optoelectrical diode can be used for multiplexed light emission and light detection modes. These permit a number of applications as explained in the sections to follow.

Again it is noted that an emerging alternative to OLEDs are Organic Light Emitting Transistors (OLETS). The present invention allows for arrangements employing OLETS to be employed in place of OLEDs and LEDs as appropriate and advantageous wherever mentioned throughout the specification.

Electronic Circuit Interfacing to LEDs Used as Light Sensors

FIGS. 11-14 depict various exemplary circuits demonstrating various exemplary approaches to detecting light with an LED. These initially introduce the concepts of received light intensity measurement (“detection”) and varying light emission intensity of an LED in terms of variations in D.C. (“direct-current”) voltages and currents. However, light intensity measurement (“detection”) can be accomplished by other means such as LED capacitance effects—for example reverse-biasing the LED to deposit a known charge, removing the reverse bias, and then measuring the time for the charge to then dissipate within the LED. Also, varying the light emission intensity of an LED can be accomplished by other means such as pulse-width-modulation—for example, a duty-cycle of 50% yields 50% of the “constant-on” brightness, a duty-cycle of 50% yields 50% of the “constant-on” brightness, etc. These, too, are provided for by the invention and will be considered again later as variations of the illustrative approaches provided below.

To begin, LED1 in FIG. 11 is employed as a photodiode, generating a voltage with respect to ground responsive to the intensity of the light received at the optically-exposed portion of the LED-structured semiconducting material. In particular, for at least a range of light intensity levels the voltage generated by LED1 increases monotonically with the received light intensity. This voltage can be amplified by a high-impedance amplifier, preferably with low offset currents. The example of FIG. 11 shows this amplification performed by a simple operational amplifier (“op amp”) circuit with fractional negative feedback, the fraction determined via a voltage divider. The gain provided by this simple op amp arrangement can be readily recognized by one skilled in the art as

1+(R_(f)/R_(g)).

The op amp produces an isolated and amplified output voltage that increases, at least for a range, monotonically with increasing light received at the light detection LED 1. Further in this example illustrative circuit, the output voltage of the op amp is directed to LED100 via current-limiting resistor R100. The result is that the brightness of light emitted by LED100 varies with the level of light received by LED1.

For a simple lab demonstration of this rather remarkable fact, one can choose a TL08x series (TL082, TL084, etc.) or equivalent op amp powered by +12 and −12 volt split power supply, R100 of ˜1KΩ, and R_(f)/R_(g) in a ratio ranging from 1 to 20 depending on the type of LED chosen. LED100 will be dark when LED1 is engulfed in darkness and will be brightly lit when LED1 is exposed to natural levels of ambient room light. For best measurement studies, LED1 could comprise a “water-clear” plastic housing (rather than color-tinted). It should also be noted that the LED1 connection to the amplifier input is of relatively quite high impedance and as such can readily pick up AC fields, radio signals, etc. and is best realized using as physically small electrical surface area and length as possible. In a robust system, electromagnetic shielding is advantageous.

The demonstration circuit of FIG. 11 can be improved, modified, and adapted in various ways (for example, by adding voltage and/or current offsets, JFET preamplifiers, etc.), but as shown is sufficient to show that a wide range of conventional LEDs can serve as pixel sensors for an ambient-room light sensor array as can be used in a camera or other room-light imaging system. Additionally, LED100 shows the role an LED can play as a pixel emitter of light.

FIG. 12 shows a demonstration circuit for the photocurrent of the LED. For at least a range of light intensity levels the photocurrent generated by LED1 increases monotonically with the received light intensity. In this exemplary circuit the photocurrent is directed to a natively high-impedance op amp (for example, a FET input op amp such as the relatively well-known LF-351) set up as an inverting current-to-voltage converter. The magnitude of the transresistance (i.e., the current-to-voltage “gain”) of this inverting current-to-voltage converter is set by the value of the feedback resistor Rf. The resultant circuit operates in a similar fashion to that of FIG. 11 in that the output voltage of the op amp increases, at least for a range, monotonically with increasing light received at the light detection LED. The inverting current-to-voltage converter inverts the sign of the voltage, and such inversion in sign can be corrected by a later amplification stage, used directly, or is preferred. In other situations it can be advantageous to not have the sign inversion, in which case the LED orientation in the circuit can be reversed, as shown in FIG. 13.

FIG. 14 shows an illustrative demonstration arrangement in which an LED can be for a very short duration of time reverse biased and then in a subsequent interval of time the resultant accumulations of charge in the junction capacitance of the LED are discharged. The decrease in charge during discharge through the resistor R results in a voltage that can be measured with respect to a predetermined voltage threshold, for example as can be provided by a (non-hysteretic) comparator or (hysteretic) Schmitt-trigger. The resulting variation in discharge time varies monotonically with the light received by the LED. The illustrative demonstration arrangement provided in FIG. 14 is further shown in the context of connects to the bidirectional I/O pin circuit for a conventional microprocessor. This permits the principal to be readily demonstrated through a simple software program operating on such a microprocessor. Additionally, as will be seen later, the very same circuit arrangement can be used to variably control the emitted light brightness of the LED by modulating the temporal pulse-width of a binary signal at one or both of the microprocessor pins.

Multiplexing Circuitry for LED Arrays

For rectangular arrays of LEDs, it is typically useful to interconnect each LED with access wiring arranged to be part of a corresponding matrix wiring arrangement. The matrix wiring arrangement is time-division multiplexed. Such time-division multiplexed arrangements can be used for delivering voltages and currents to selectively illuminate each individual LED at a specific intensity level (including very low or zero values so as to not illuminate).

An example multiplexing arrangement for a two-dimensional array of LEDs is depicted in FIG. 15. Here each of a plurality of normally-open analog switches are sequentially closed for brief disjointed intervals of time. This allows the selection of a particular subset (here, a column) of LEDs to be grounded while leaving all other LEDs in the array not connected to ground. Each of the horizontal lines then can be used to connect to exactly one grounded LED at a time. The plurality of normally-open analog switches in FIG. 15 may be controlled by an address decoder so that the selected subset can be associated with a unique binary address, as suggested in FIG. 16. The combination of the plurality of normally-open analog switches together with the address decoder form an analog line selector. By connecting the line decoder's address decoder input to a counter, the columns of the LED array can be sequentially scanned.

FIG. 17 depicts an exemplary adaptation of the arrangement of FIG. 16 together to form a highly scalable LED array display that also functions as a light field detector. The various multiplexing switches in this arrangement can be synchronized with the line selector and mode control signal so that each LED very briefly provides periodically updated detection measurement and is free to emit light the rest of the time. A wide range of variations and other possible implementations are possible and implemented in various products.

Such time-division multiplexed arrangements can alternatively be used for selectively measuring voltages or currents of each individual LED. Further, the illumination and measurement time-division multiplexed arrangements themselves can be time-division multiplexed, interleaved, or merged in various ways. As an illustrative example, the arrangement of FIG. 17 can be reorganized so that the LED, mode control switch, capacitor, and amplifiers are collocated, for example as in the illustrative exemplary arrangement of FIG. 18. Such an arrangement can be implemented with, for example, three MOSFET switching transistor configurations, two MOSFET amplifying transistor configurations, a small-area/small-volume capacitor, and an LED element (that is, five transistors, a small capacitor, and an LED). This can be treated as a cell which is interconnected to multiplexing switches and control logic. A wide range of variations and other possible implementations are possible and the example of FIG. 17 is in no way limiting. For example, the arrangement of FIG. 17 can be reorganized to decentralize the multiplexing structures so that the LED, mode control switch, multiplexing and sample/hold switches, capacitor, and amplifiers are collocated, for example as in the illustrative exemplary arrangement of FIG. 19. Such an arrangement can be implemented with, for example, three MOSFET switching transistor configurations, two MOSFET amplifying transistor configurations, a small-area/small-volume capacitor, and an LED element (that is, five transistors, a small capacitor, and an LED). This can be treated as a cell whose analog signals are directly interconnected to busses. Other arrangements are also possible.

The discussion and development thus far are based on the analog circuit measurement and display arrangement of FIG. 11 that in turn leverages the photovoltaic properties of LEDs. With minor modifications clear to one skilled in the art, the discussion and development thus far can be modified to operate based on the analog circuit measurement and display arrangements of FIG. 12 and FIG. 13 that leverage the photocurrrent properties of LEDs.

FIG. 20, FIG. 21, and FIG. 22 depict an example of how the digital circuit measurement and display arrangement of FIG. 14 (that in turn leverages discharge times for accumulations of photo-induced charge in the junction capacitance of the LED) can be adapted into the construction developed thus far. FIG. 20 adapts FIG. 14 to additional include provisions for illuminating the LED with a pulse-modulated emission signal. Noting that the detection process described earlier in conjunction with FIG. 14 can be confined to unperceivably short intervals of time, FIG. 21 illustrates how a pulse-width modulated binary signal may be generated during LED illumination intervals to vary LED emitted light brightness. FIG. 22 illustrates an adaptation of the tri-state and Schmitt-trigger/comparator logic akin to that illustrated in the microprocessor I/O pin interface that may be used to sequentially access subsets of LEDs in an LED array as described in conjunction with FIG. 15 and FIG. 16.

FIGS. 23-25 depict exemplary state diagrams for the operation of the LED and the use of input signals and output signals described above. From the viewpoint of the binary mode control signal there are only two states: a detection state and an emission state, as suggested in FIG. 23. From the viewpoint of the role of the LED in a larger system incorporating a multiplexed circuit arrangement such as that of FIG. 17, there may a detection state, an emission state, and an idle state (where there is no emission nor detection occurring), obeying state transition maps such as depicted in FIG. 24 or FIG. 25. At a further level of detail, there are additional considerations:

-   -   To emit light, a binary mode control signal can be set to “emit”         mode (causing the analog switch to be closed) and the emission         light signal must be of sufficient value to cause the LED to         emit light (for example, so that the voltage across the LED is         above the “turn-on” voltage for that LED).         -   If the binary mode control signal is in “emit” mode but the             emission light signal is not of such sufficient value, the             LED will not illuminate. This can be useful for brightness             control (via pulse-width modulation), black-screen display,             and other uses. In some embodiments, this may be used to             coordinate the light emission of neighboring LEDs in an             array while a particular LED in the array is in detection             mode.         -   If the emission light signal of such sufficient value but             the binary mode control signal is in “detect” mode, the LED             will not illuminate responsive to the emission light signal.             This allows the emission light signal to be varied during a             time interval when there is no light emitted, a property             useful for multiplexing arrangements.     -   During a time interval beginning with the change of state of the         binary mode control signal to some settling-time period         afterwards, the detection output and/or light emission level may         momentarily not be accurate.     -   To detect light, the binary mode control signal must be in         “detect” mode (causing the analog switch to be open). The         detected light signal may be used by a subsequent system or         ignored. Intervals where the circuit is in detection mode but         the detection signal is ignored may be useful for multiplexing         arrangement, in providing guard-intervals for settling time, to         coordinate with the light emission of neighboring LEDs in an         array, etc.

FIG. 26 depicts an exemplary state transition diagram reflecting the above considerations. The top “Emit Mode” box and bottom “Detect Mode” box reflect the states of an LED from the viewpoint of the binary mode control signal as suggested by FIG. 23. The two “Idle” states (one in each of the “Emit Mode” box and “Detect Mode” box) of FIG. 26 reflect (at least in part) the “Idle” state suggested in FIG. 24 and/or FIG. 25. Within the “Emit Mode” box, transitions between “Emit” and “Idle” may be controlled by emit signal multiplexing arrangements, algorithms for coordinating the light emission of an LED in an array while a neighboring LED in the array is in detection mode, etc. Within the “Detect Mode” box, transitions between “Detect” and “Idle” may be controlled by independent or coordinated multiplexing arrangements, algorithms for coordinating the light emission of an LED in an array while a neighboring LED in the array is in detection mode, etc. In making transitions between states in the boxes, the originating and termination states may be chosen in a manner advantageous for details of various multiplexing and feature embodiments. Transitions between the groups of states within the two boxes correspond to the vast impedance shift invoked by the switch opening and closing as driven by the binary mode control signal. In FIG. 26, the settling times between these two groups of states are gathered and regarded as a transitional state.

As mentioned earlier, the amplitude of light emitted by an LED can be modulated to lesser values by means of pulse-width modulation (PWM) of a binary waveform. For example, if the binary waveform oscillates between fully illuminated and non-illuminated values, the LED illumination amplitude will be perceived roughly as 50% of the full-on illumination level when the duty-cycle of the pulse is 50%, roughly as 75% of the full-on illumination level when the duty-cycle of the pulse is 75%, roughly as 10% of the full-on illumination level when the duty-cycle of the pulse is 10%, etc. Clearly the larger fraction of time the LED is illuminated (i.e., the larger the duty-cycle), the brighter the perceived light observed emitted from the LED.

Stacked OLEDs (“SOLED”) as Optical Diode Elements for Use in the Invention

FIG. 27 (adapted from G. Gu, G. Parthasarathy, P. Burrows, T. Tian, I. Hill, A. Kahn, S. Forrest, “Transparent stacked organic light emitting devices. I. Design principles and transparent compound electrodes,” Journal of Applied Physics, October 1999, vol. 86 no. 8, pp. 4067-4075) depicts an exemplary high-level structure of a three-color transparent Stacked OLED (“SOLED”) element as has been developed for use in light-emitting color displays.

The present invention provides for a three-color transparent SOLED element such as those depicted in FIG. 27 or of other forms developed for use in light-emitting color displays to be used as-is as a color transparent light sensor.

Alternatively, the present invention provides for analogous structures to be used to implement a three-color transparent light sensor, for example, with reference to FIG. 10, by replacing optoelectrical diode materials, structure, and fabrication approaches 1923 optimized for light emission performance 1902 with optoelectrical diode materials, structure, and fabrication approaches 1923 optimized for light detection performance 1901. The present invention additionally provides for a three-color transparent SOLED element such as those depicted in FIG. 27 or of other forms developed for use in light-emitting color displays to employ specific optoelectrical diode materials, structure, and fabrication approaches 1923 to be adjusted to co-optimize an optoelectrical diode for both good light detection performance 1901 and light emission performance 1902 versus cost 1903. The resulting structure can be used for color light emission, color light sensing, or both.

The invention additionally provides for the alternative use of similar or related structures employing OLETs.

Arrayed OLEDs as Optical Diode Elements for Use in the Invention

FIG. 28 (adapted from http://www.displayblog.com/2009/03/26/samsung-oled-pentile-matrix-next-iphone-oled-display/ (visited Mar. 23, 2011) depicts a conventional “RGB stripe” OLED array as used in a variety of OLED display products. FIG. 29 (also adapted from http://www.displayblog.com/2009/03/26/samsung-oled-pentile-matrix-next-iphone-oled-display/ (visited Mar. 23, 2011) depicts a representation of the “PenTile Matrix” OLED array as attributed to Samsung which provides good display performance with a 33% reduction in pixel element count.

The present invention provides for arrays of OLED elements such as those depicted in FIG. 28 and FIG. 29 other forms developed for use in light-emitting color displays to be used as-is as a color light sensors. This permits OLED elements in arrays such as those depicted in FIG. 28 and FIG. 29 or of other forms developed for use in light-emitting color displays to be used for light field sensing in accordance with aspects of the present invention.

Alternatively, the present invention provides for analogous structures to be used to implement a three-color transparent light sensor, for example, with reference to FIG. 10, by replacing optoelectrical diode materials, structure, and fabrication approaches 1923 optimized for light emission performance 1902 with optoelectrical diode materials, structure, and fabrication approaches 1923 optimized for light detection performance 1901. The present invention additionally provides for OLED elements in arrays such as those depicted in FIG. 27 or of other forms developed for use in light-emitting color displays to employ specific optoelectrical diode materials, structure, and fabrication approaches 1923 to be adjusted to co-optimize an optoelectrical diode for both good light detection performance 1901 and light emission performance 1902 versus cost 1903. The resulting structure can be used for color light emission, color light sensing, or both.

The invention additionally provides for the alternative use of similar or related structures employing OLETs.

Light Field Sensor Embodiments

In an embodiment, various materials, physical processes, structures, and fabrication techniques used in creating an array of color inorganic LEDs, OLEDs, OLETs, or related devices and associated co-located electronics (such as FETs, resistors, and capacitors) can be used as-is to create an array of color inorganic LEDs, OLEDs, OLETs, or related devices well-suited as a color light-field sensor. An exemplary general framework underlying such an arrangement is described in pending U.S. patent application Ser. No. 12/419,229 (priority date Jan. 27, 1999), pending U.S. patent application Ser. No. 12/471,275 (priority date May 25, 2008), and in pending U.S. patent application Ser. Nos. 13/072,588 and 61/517,454.

In an embodiment, various materials, physical processes, structures, and fabrication techniques used in creating an array of color inorganic LEDs, OLEDs, OLETs, or related devices and associated co-located electronics (such as FETs, resistors, and capacitors) can be co-optimized to create an array of color inorganic LEDs, OLEDs, OLETs, or related devices well-suited as a color light-field sensor. An exemplary general framework underlying such an arrangement is described in pending U.S. patent application Ser. No. 12/419,229 (priority date Jan. 27, 1999), pending U.S. patent application Ser. No. 12/471,275 (priority date May 25, 2008), and in pending U.S. patent application Ser. Nos. 13/072,588 and 61/517,454.

In an embodiment, at least three inorganic LEDs, OLEDs, or related devices are transparent. In an embodiment, the at least three transparent inorganic LEDs, OLEDs, or related devices are comprised in an array that is overlaid on a display such as an LCD.

Operation as a Combination Light Field Sensor and Display

In embodiment provided for by the invention, each inorganic LED, OLED, or related device in an array of color inorganic LEDs, OLEDs, OLETs, or related devices can be alternately used as a photodetector or as a light emitter. The state transitions of each inorganic LED, OLED, or related device in the array of color inorganic LEDs, OLEDs, OLETs, or related devices among the above states can be coordinated in a wide variety of ways to afford various multiplexing, signal distribution, and signal gathering schemes as can be advantageous. An exemplary general framework underlying such an arrangement is described in pending U.S. patent application Ser. No. 12/419,229 (priority date Jan. 27, 1999), pending U.S. patent application Ser. No. 12/471,275 (priority date May 25, 2008), and in pending U.S. patent application Ser. Nos. 13/072,588 and 61/517,454.

In embodiment provided for by the invention, each inorganic LED, OLED, or related device in an array of inorganic LEDs, OLEDs, or related devices can, at any one time, be in one of three states:

-   -   A light emission state,     -   A light detection state,     -   An idle state,         as can be advantageous for various operating strategies.

The state transitions of each inorganic LED, OLED, or related device in the array of color inorganic LEDs, OLEDs, OLETs, or related devices among the above states can be coordinated in a wide variety of ways to afford various multiplexing, signal distribution, and signal gathering schemes as can be advantageous. An exemplary general framework underlying such an arrangement is described in pending U.S. patent application Ser. No. 12/419,229 (priority date Jan. 27, 1999), pending U.S. patent application Ser. No. 12/471,275 (priority date May 25, 2008), and in pending U.S. patent application Ser. Nos. 13/072,588 and 61/517,454.

Accordingly, in an embodiment various materials, physical processes, structures, and fabrication techniques used in creating an array of color inorganic LEDs, OLEDs, OLETs, or related devices and associated co-located electronics (such as FETs, resistors, and capacitors) can be used as-is, adapted, and/or optimized so that the array of color inorganic LEDs, OLEDs, OLETs, or related devices to work well as both a color image display and color light-field sensor. An exemplary general framework underlying such an arrangement is described in pending U.S. patent application Ser. No. 12/419,229 (priority date Jan. 27, 1999), pending U.S. patent application Ser. No. 12/471,275 (priority date May 25, 2008), and in pending U.S. patent application Ser. Nos. 13/072,588 and 61/517,454.

Physical Structures for Combination Light Field Sensor and Display

The capabilities described thus far can be combined with systems and techniques to be described later in a variety of physical configurations and implementations. A number of example physical configurations and implementations are described here which provide various enablements and advantages to various embodiments and implemetantions of the invention and their applications. Many variations and alternatives are possible and are accordingly anticipated by the invention, and the example physical configurations and implementations are in no way limiting of the invention.

When implementing lensless imaging cameras as taught in U.S. patent application Ser. Nos. 12/419,229 (priority date Jan. 27, 1999), 12/471,275 (priority date May 25, 2008), 13/072,588, and 61/517,454, an optical vignetting arrangement is needed for the light-sensing LEDs. This can be implemented in various ways. In one example approach, LEDs in the LED array themselves can be structured so that light-sensing elements (including photodiodes or LEDs used in light-sensing modes) are partially enveloped in a well comprising walls formed in associating with at least light-emitting LEDs in the LED array. In a variation of this the light emitting LEDs can also be used in a light sensing mode, in implementing a tactile user interface arrangement as enabled by the present invention. In another variation, other types of light sensing elements (for example, photodiodes) can in implementing an optical tactile user interface arrangement as enabled by the present invention. FIG. 30 depicts an exemplary embodiment comprising an LED array preceded by a vigneting arrangement as is useful for implementing a lensless imaging camera as taught in U.S. patent application Ser. Nos. 12/419,229 (priority date Jan. 27, 1999), 12/471,275 (priority date May 25, 2008), 13/072,588, and 61/517,454. In another approach to be described shortly, an LCD otherwise used for display can be used to create vignetting apertures.

The invention provides for inclusion of coordinated multiplexing or other coordinated between the LED array and LCD as needed or advantageous. In another approach, a vignetting arrangement is created as a separate structure and overlaid atop the LED array. Other related arrangements and variations are possible and are anticipated by the invention. The output of the light field sensor can also or alternatively be used to implement a tactile user interface or proximate hand gesture user interface as described later in the detailed description.

Leaving the vignetting considerations involved in lensless imaging, attention is now directed to arrangements wherein a transparent LED array, for example implemented with arrays of transparent OLEDs interconnected with transparent conductors, is overlaid atop an LCD display. The transparent conductors can be comprised of materials such as indium tin oxide, fluorine-doped tin oxide (“FTO”), doped zinc oxide, organic polymers, carbon nanotubes, graphene ribbons, etc. FIG. 31 depicts an exemplary implementation comprising a transparent OLED array overlaid upon an LCD visual display, which is in turn overlaid on a (typically) LED backlight used to create and direct light though the LCD visual display from behind. Such an arrangement may be used to implement an optical tactile user interface arrangement as enabled by the present invention. Other related arrangements and variations are possible and are anticipated by the invention. The invention provides for inclusion of coordinated multiplexing or other coordinated between the OLED array and LCD as needed or advantageous. It is noted in one embodiment the LCD and LED array can be fabricated on the same substrate, the first array layered atop the second (or visa versa) while in another embodiment the two LED arrays can be fabricated separately and later assembled together to form layered structure. Other related arrangements and variations are possible and are anticipated by the invention.

FIG. 32 depicts an exemplary implementation comprising a first (transparent OLED) LED array used for at least optical sensing overlaid upon a second LED array used for at least visual display. In an embodiment, the second LED array can be an OLED array. In an embodiment, either or both of the LED arrays can comprise photodiodes. Such an arrangement can be employed to allow the first array to be optimized for one or more purposes, at least one being sensing, and the second LED array to be optimized for one or more purposes, at least one being visual display. Such an arrangement may be used to implement an optical tactile user interface arrangement as enabled by the present invention. In one approach the second LED array is used for both visual display and tactile user interface illumination light and the first (transparent OLED) LED array is used for tactile user interface light sensing. In another approach, the first (transparent OLED) LED array is used for both tactile user interface illumination light and light sensing, while the second LED array is used for visual display. In an embodiment, the second LED array is used for visual display and further comprises vignetting structures (as described above) and serves as a light field sensor to enable the implementation of a lensless imaging camera. Such an arrangement can be used to implement a light field sensor and a lensless imaging camera as described earlier. Other related arrangements and variations are possible and are anticipated by the invention. The invention provides for inclusion of coordinated multiplexing or other coordinated between the first LED array and second LED array as needed or advantageous. It is noted in one embodiment the two LED arrays can be fabricated on the same substrate, the first array layered atop the second (or visa versa) while in another embodiment the two LED arrays can be fabricated separately and later assembled together to form layered structure. Other related arrangements and variations are possible and are anticipated by the invention.

FIG. 33 depicts an exemplary implementation comprising a first (transparent OLED) LED array used for at least visual display overlaid upon a second LED array used for at least optical sensing. In an embodiment, the second LED array can be an OLED array. In an embodiment, either or both of the LED arrays can comprise photodiodes. Such an arrangement can be employed to allow the first array to be optimized for to be optimized for other purposes, at least one being visual display, and the second LED array to be optimized for one or more purposes, at least one being sensing. Such an arrangement may be used to implement an optical tactile user interface arrangement as enabled by the present invention. In one approach the first LED array is used for both visual display and tactile user interface illumination light and the second (transparent OLED) LED array is used for tactile user interface light sensing.

In another approach, the second (transparent OLED) LED array is used for both tactile user interface illumination light and light sensing, while the first LED array is used for visual display. In an embodiment, the second LED array comprises vignetting structures (as described above) and serves as a light field sensor to enable the implementation of a lensless imaging camera. Other related arrangements and variations are possible and are anticipated by the invention. The invention provides for inclusion of coordinated multiplexing or other coordinated between the first LED array and second LED array as needed or advantageous. It is noted in one embodiment the two LED arrays can be fabricated on the same substrate, the first array layered atop the second (or visa versa) while in another embodiment the two LED arrays can be fabricated separately and later assembled together to form layered structure. Other related arrangements and variations are possible and are anticipated by the invention.

FIG. 34 depicts an exemplary implementation comprising an LCD display, used for at least visual display and vignette formation, overlaid upon a second LED array, used for at least backlighting of the LCD and optical sensing. In an embodiment, the LED array can be an OLED array. In an embodiment, the LED array can comprise also photodiodes. Such an arrangement can be used to implement an optical tactile user interface arrangement as enabled by the present invention. Such an arrangement can be used to implement a light field sensor and a lensless imaging camera as described earlier. The invention provides for inclusion of coordinated multiplexing or other coordinated between the LCD and LED array as needed or advantageous. It is noted in one embodiment the LCD and LED array can be fabricated on the same substrate, the first array layered atop the second (or visa versa) while in another embodiment the two LED arrays can be fabricated separately and later assembled together to form layered structure. Other related arrangements and variations are possible and are anticipated by the invention.

Use of a LED Array as “Multi-Touch” Tactile Sensor Array

Multitouch sensors on cellphones, smartphones, PDAs, tablet computers, and other such devices typically utilize a capacitive matrix proximity sensor. FIG. 35 an exemplary arrangement employed in contemporary cellphones, smartphones, PDAs, tablet computers, and other portable devices wherein a transparent capacitive matrix proximity sensor is overlaid over an LCD display, which is in turn overlaid on a (typically LED) backlight used to create and direct light though the LCD display from behind. Each of the capacitive matrix and the LCD have considerable associated electronic circuitry and software associated with them.

FIG. 36 depicts an exemplary modification of the arrangement depicted in FIG. 35 wherein the LCD display and backlight are replaced with an OLED array used as a visual display. Such an arrangement has started to be incorporated in recent contemporary cellphone, smartphone, PDA, tablet computers, and other portable device products by several manufacturers. Note the considerable reduction in optoelectronic, electronic, and processor components over the arrangement depicted in FIG. 35. This is one of the motivations for using OLED displays in these emerging product implementations.

FIG. 37 depicts an exemplary arrangement provided for by the invention comprising only a LED array. The LEDs in the LED array may be OLEDs or inorganic LEDs. Such an arrangement can be used as a tactile user interface, or as a combined a visual display and tactile user interface, as will be described next. Note the considerable reduction in optoelectronic, electronic, and processor components over the both the arrangement depicted in FIG. 35 and the arrangement depicted in FIG. 36. This is one of the advantages of many embodiments of the present invention.

Arrays of inorganic-LEDs have been used to create a tactile proximity sensor array as taught by Han in U.S. Pat. No. 7,598,949 and as depicted in the video available at http://cs.nyu.edu/about.jhan/ledtouch/index.html). FIG. 38 depicts a representative exemplary arrangement wherein light emitted by neighboring LEDs is reflected from a finger (or other object) back to an LED acting as a light sensor.

In its most primitive form, such LED-array tactile proximity array implementations need to be operated in a darkened environment (as seen in the video available at http://cs.nyu.edu/about.jhan/ledtouch/index.html). The invention provides for additional systems and methods for not requiring darkness in the user environment in order to operate the LED array as a tactile proximity sensor.

In one approach, potential interference from ambient light in the surrounding user environment can be limited by using an opaque pliable and/or elastically deformable surface covering the LED array that is appropriately reflective (directionally, amorphously, etc. as may be advantageous in a particular design) on the side facing the LED array. Such a system and method can be readily implemented in a wide variety of ways as is clear to one skilled in the art.

In another approach, potential interference from ambient light in the surrounding user environment can be limited by employing amplitude, phase, or pulse width modulated circuitry and/or software to control the light emission and receiving process. For example, in an implementation the LED array can be configured to emit modulated light that is modulated at a particular carrier frequency and/or with a particular time-variational waveform and respond to only modulated light signal components extracted from the received light signals comprising that same carrier frequency or time-variational waveform. Such a system and method can be readily implemented in a wide variety of ways as is clear to one skilled in the art.

The light measurements used for implementing a tacile user interface can be from unvignetted LEDs, unvignetted photodiodes, vignetted LEDs, vignetted photodiodes, or combinations of two or more of these.

Separate Sensing and Display Elements in an LED Array

In one embodiment provided for by the invention, some LEDs in an array of LEDs are used as photodetectors while other elements in the array are used as light emitters. The light emitter LEDs can be used for display purposes and also for illuminating a finger (or other object) sufficiently near the display. FIG. 39 depicts an exemplary arrangement wherein a particular LED designated to act as a light sensor is surrounded by immediately-neighboring element designated to emit light to illuminate the finger for example as depicted in FIG. 38. Other arrangements of illuminating and sensing LEDs are of course possible and are anticipated by the invention.

It is also noted that by dedicating functions to specific LEDs as light emitters and other elements as light sensors, it is possible to optimize the function of each element for its particular role. For example, in an example embodiment the elements used as light sensors can be optimized photodiodes. In another example embodiment, the elements used as light sensors can be the same type of LED used as light emitters. In yet another example embodiment, the elements used as light sensors can be LEDs that are slightly modified versions the of type of LED used as light emitters.

In an example embodiment, the arrangement described above can be implemented only as a user interface. In an example implementation, the LED array can be implemented as a transparent OLED array that can be overlaid atop another display element such as an LCD or another LED array. In an implementation, LEDs providing user interface illumination provide light that is modulated at a particular carrier frequency and/or with a particular time-variational waveform as described earlier.

In an alternative example embodiment, the arrangement described above can serve as both a display and a tactile user interface. In an example implementation, the light emitting LEDs in the array are time-division multiplexed between visual display functions and user interface illumination functions. In another example implementation, some light emitting LEDs in the array are used for visual display functions while light emitting LEDs in the array are used for user interface illumination functions. In an implementation, LEDs providing user interface illumination provide modulated illumination light that is modulated at a particular carrier frequency and/or with a particular time-variational waveform. In yet another implementation approach, the modulated illumination light is combined with the visual display light by combining a modulated illumination light signal with a visual display light signal presented to each of a plurality of LEDs within the in the LED array. Such a plurality of LEDs can comprise a subset of the LED array or can comprise the entire LED array.

FIG. 40 depicts an exemplary arrangement wherein a particular LED designated to act as a light sensor is surrounded by immediately-neighboring LEDs designated to serve as a “guard area,” for example not emitting light, these in turn surrounded by immediately-neighboring LEDs designated to emit light used to illuminate the finger for example as depicted in FIG. 38. Such an arrangement can be implemented in various physical and multiplexed ways as advantageous to various applications or usage environments.

In an embodiment, the illumination light used for tactile user interface purposes can comprise an invisible wavelength, for example infrared or ultraviolet.

Sequenced Sensing and Display Modes for LEDs in an LED Array

In another embodiment provided for by the invention, each LED in an array of LEDs can be used as a photodetector as well as a light emitter wherein each individual LED can either transmit or receive information at a given instant. In an embodiment, each LED in a plurality of LEDs in the LED array can sequentially be selected to be in a receiving mode while others adjacent or near to it are placed in a light emitting mode. Such a plurality of LEDs can comprise a subset of the LED array or can comprise the entire LED array. A particular LED in receiving mode can pick up reflected light from the finger, provided by said neighboring illuminating-mode LEDs. In such an approach, local illumination and sensing arrangements such as that depicted FIG. 39 (or variations anticipated by the invention) can be selectively implemented in a scanning and multiplexing arrangement.

FIG. 40 depicts an exemplary arrangement wherein a particular LED designated to act as a light sensor is surrounded by immediately-neighboring LEDs designated to serve as a “guard” area, for example not emitting light, these in turn surrounded by immediately-neighboring LEDs designated to emit light used to illuminate the finger for example as depicted in FIG. 38. Such an arrangement can be implemented in various multiplexed ways as advantageous to various applications or usage environments.

In an alternative example embodiment, the arrangement described above can serve as both a display and a tactile user interface. In an example implementation, the light emitting LEDs in the array are time-division multiplexed between visual display functions and user interface illumination functions. In another example implementation, some light emitting LEDs in the array are used for visual display functions while light emitting LEDs in the array are used for user interface illumination functions. In an implementation, LEDs providing user interface illumination provide modulated illumination light that is modulated at a particular carrier frequency and/or with a particular time-variational waveform. In yet another implementation approach, the modulated illumination light is combined with the visual display light by combining a modulated illumination light signal with a visual display light signal presented to each of a plurality of LEDs within the in the LED array. Such a plurality of LEDs can comprise a subset of the LED array or can comprise the entire LED array.

Use of a LED Array in Implementing a Lensless Imaging Camera

In an embodiment, various materials, physical processes, structures, and fabrication techniques used in creating an array of color inorganic LEDs, OLEDs, OLETs, or related devices and associated co-located electronics (such as FETs, resistors, and capacitors) can be used as-is, adapted, and/or optimized so as to create an array of color inorganic LEDs, OLEDs, OLETs, or related devices that is well-suited as for operation as a color lensless imaging camera according to the general framework described in pending U.S. patent application Ser. No. 12/419,229 (priority date Jan. 27, 1999), pending U.S. patent application Ser. No. 12/471,275 (priority date May 25, 2008), and in pending U.S. patent application Ser. Nos. 13/072,588 and 61/517,454.

Co-pending U.S. patent application Ser. Nos. 12/471,275 (priority date Jan. 27, 1999), 12/419,229, 13/072,588, and 61/517,454 teach, among other things, the use of an LED array, outfitted with micro-optical arrangements that create optical occulting/vignetting and interfaced with a new type of “image formation” signal processing, as a (monochrome or color) camera for image or video applications.

Image formation is performed without a conventional large shared lens and associated separation distance between lens and image sensor, resulting in a “lensless camera.”

Further, the similarities between the spectral detection band and the spectral emission bands of each of a plurality of types of colored-light LED may be used to create a color light-field sensor from a color LED array display such as that currently employed in “LED TV” products, large outdoor color-image LED displays (as seen in advertising signs and sports stadiums), and recently (in the form of OLED displays) in Samsung Smartphones.

In an embodiment, the various materials, physical processes, structures, and fabrication techniques used in creating the LED array and associated co-located electronics (such as FETs, resistors, and capacitors) may be used to further co-optimize a high performance monochrome LED array or color LED array to work well as both an image display and light-field sensor compatible with synthetic optics image formation algorithms using methods, systems, and process such as those aforedescribed.

Operation as a Combination Color Lensless Imaging Camera and Color Visual Display

The examples above employ an LED array multiplexed in between light-emitting modes and light-sensing modes. The examples above employ an LED array to be used in visual (image, video, GUI) display modes and lensless imaging camera modes. The invention provides for these to be integrated together into a common system, leveraging one or more of a shared electronics infrastructure, shared processor infrastructure, and shared algorithmic infrastructure.

In an embodiment, an array of color inorganic LEDs, OLEDs, OLETs, or related devices, together with associated signal processing aspects of the invention, can be adapted to function as both a color image display and color light-field sensor compatible with synthetic optics image formation algorithms using methods, systems, and process such as those described in pending U.S. patent application Ser. No. 12/419,229 (priority date Jan. 27, 1999), pending U.S. patent application Ser. No. 12/471,275 (priority date May 25, 2008), and in pending U.S. patent application Ser. Nos. 13/072,588 and 61/517,454.

Either of these arrangements allows for a common processor to be used for display and camera functionalities. The result dramatically decreases the component count and system complexity for contemporary and future mobile devices such as cellphones, smartphones, PDAs tablet computers, and other such devices.

Use of a LED Array as an Integrated Camera and a Display Simultaneously

The invention further provides for a common LED array multiplexed in between light-emitting display modes and light-sensing lensless imaging camera modes. Here the LED array to be time multiplexed between “image capture” and “image display” modes so as to operate as an integrated camera/display. The invention provides for these to be integrated together into a common system, leveraging one or more of a shared electronics infrastructure, shared processor infrastructure, and shared algorithmic infrastructure.

The integrated camera/display operation removes the need for a screen-direction camera and interface electronics in mobile devices. The integrated camera/display operation can also improve eye contact in mobile devices.

Employing these constructions, the invention provides for an LED array image display, used in place of a LCD image display, to serve as a time-multiplexed array of light emitter and light detector elements. The resulting system does not require an interleaving or stacking of functionally-differentiated (with respect to light detection and light emission) elements. This is particularly advantageous as there is a vast simplification in manufacturing and in fact close or precise alignment with current LED array image display manufacturing techniques and existing LED array image display products.

Either of these arrangements allows for a common processor to be used for display and camera functionalities. The result dramatically decreases the component count and system complexity for contemporary and future mobile devices such as cellphones, smartphones, PDAs, tablet computers, and other such devices.

Use of a LED Array in Implementing a (Tactile User Interface) Touch Screen Sensor

In an embodiment, an array of color inorganic LEDs, OLEDs, OLETs, or related devices, together with associated signal processing aspects of the invention, can be used to implement a tactile (touch-based) user interface sensor.

Use of a LED Array in Implementing a Combination (Tactile User Interface) Touch Screen Sensor and Color Visual Image Display

In an embodiment, an array of color inorganic LEDs, OLEDs, OLETs, or related devices, together with associated signal processing aspects of the invention, can be adapted to function as both a color image visual display and light-field sensor which can be used to implement a tactile user interface.

The integrated tactile user interface sensor capability can remove the need for a tactile user interface sensor (such as a capacitive matrix proximity sensor) and associated components.

Either of these arrangements allows for a common processor to be used for display and camera functionalities. The result dramatically decreases the component count and system complexity for contemporary and future mobile devices such as cellphones, smartphones, PDAs, tablet computers, and other such devices.

Use of a LED Array as an Integrated Camera, Display, and (Tactile User Interface) Touch Screen

In an approach to the invention, the LED array is multiplexed among display, camera, and tactile user interface sensor modalities. In an exemplary associated embodiment of the invention, an LED array can be used as a display, camera, and touch-based user interface sensor.

The integrated camera/display operation removes the need for a screen-direction camera and interface electronics in mobile devices. The integrated camera/display operation can also improve eye contact in mobile devices.

The integrated tactile user interface sensor capability can remove the need for a tactile user interface sensor (such as a capacitive matrix proximity sensor) and associated components.

Either of these arrangements allows for a common processor to be used for display, camera, and tactile user interface sensor functionalities. The result dramatically decreases the component count and system complexity for contemporary and future mobile devices such as smartphones PDAs, tablet computers, and other such devices.

Use of a LED Array in Implementing a Proximate Gesture User Interface Sensor

In an embodiment, an array of color inorganic LEDs, OLEDs, OLETs, or related devices, together with associated signal processing aspects of the invention, can be adapted to function as both an image display and light-field sensor which can be used to implement a proximate (hand image) gesture user interface sensor as, for example, replacing the photodiode sensor arrangement used in the M.I.T. BI-DI user interface. In one approach, the M.I.T. BI-DI photodiode sensor arrangement behind the LCD array can be replaced with an array of inorganic LEDs, OLEDs, or related devices as provided for in the current invention. In another approach, the M.I.T. BI-DI photodiode sensor arrangement behind the LCD array, the LCD itself, and the associated backlight can be replaced with an array of inorganic LEDs, OLEDs, or related devices as provided for in the current invention.

The integrated proximate (hand image) gesture user interface capability can remove the need for a tactile user interface sensor (such as a capacitive matrix proximity sensor) and associated components.

Either of these arrangements allows for a common processor to be used for display, camera, and tactile user interface sensor functionalities. The result dramatically decreases the component count and system complexity for contemporary and future mobile devices such as cellphones, smartphones, PDAs, tablet computers, and other such devices.

Use in Implementing a Combination Proximate Gesture User Interface and Visual Image Display

In an embodiment, an array of color inorganic LEDs, OLEDs, OLETs, or related devices, together with associated signal processing aspects of the invention, can be adapted to function as both a visual image display and light-field sensor which can be used to implement a proximate gesture user interface sensor as, for example, replacing the photodiode sensor and LCD display arrangement used in the M.I.T. BI-DI user interface. In an embodiment an array of inorganic LEDs, OLEDs, or related devices can be adapted to function as both an image display and light-field sensor which can be used to implement a tactile user interface sensor, and also as a visual display.

The integrated proximate (hand image) gesture user interface capability can remove the need for a tactile user interface sensor (such as a capacitive matrix proximity sensor) and associated components.

Either of these arrangements allows for a common processor to be used for display, camera, and tactile user interface sensor functionalities. The result dramatically decreases the component count and system complexity for contemporary and future mobile devices such as cellphones, smartphones, PDAs, tablet computers, and other such devices.

Use in Implementing a Combination Proximate Gesture User Interface Sensor, Lensless Imaging Camera, and Visual Image Display

In an embodiment, an array of color inorganic LEDs, OLEDs, OLETs, or related devices, together with associated signal processing aspects of the invention, can be adapted to function as both an image display and light-field sensor which can be used to implement a proximate gesture user interface sensor, lensless imaging camera, and visual image display.

The integrated camera/display operation removes the need for a screen-direction camera and interface electronics in mobile devices. The integrated camera/display operation can also improve eye contact in mobile devices.

The integrated proximate (hand image) gesture user interface capability can remove the need for a tactile user interface sensor (such as a capacitive matrix proximity sensor) and associated components.

Either of these arrangements allows for a common processor to be used for display, camera, and tactile user interface sensor functionalities. The result dramatically decreases the component count and system complexity for contemporary and future mobile devices such as cellphones, smartphones, PDAs, tablet computers, and other such devices.

Use in Implementing a Combination Proximate Gesture User Interface, Tactile User Interface (Touchscreen), and Visual Image Display

In an embodiment, an array of color inorganic LEDs, OLEDs, OLETs, or related devices, together with associated signal processing aspects of the invention, can be adapted to function as both an image display and light-field sensor which can be used to implement a proximate gesture user interface, tactile user interface (touchscreen), and visual image display.

Further, the integrated combination of a tactile user interface (touch screen) capability and a proximate (hand image) gesture user interface capability can provide a more flexible, sophisticated, and higher accuracy user interface.

Further, as the integrated tactile user interface (touch screen) and a proximate (hand image) gesture user interface capabilities employ the light filed sensor modalities for the LED array, this approach can remove the need for a tactile user interface sensor (such as a capacitive matrix proximity sensor) and associated components.

Either of these arrangements allows for a common processor to be used for display, camera, proximate gesture user interface, and tactile user interface (touch screen) functionalities. The result dramatically decreases the component count and system complexity for contemporary and future mobile devices such as cellphones, smartphones, PDAs, tablet computers, and other such devices.

Use in Implementing a Combination Proximate Gesture User Interface, Tactile User Interface (Touchscreen), Lensless Imaging Camera, and Visual Image Display

In an embodiment, an array of color inorganic LEDs, OLEDs, OLETs, or related devices, together with associated signal processing aspects of the invention, can be adapted to function as both an image display and light-field sensor which can be used to implement a proximate gesture user interface, tactile user interface (touchscreen), lensless imaging camera, and visual image display.

The integrated camera/display operation removes the need for a screen-direction camera and interface electronics in mobile devices. The integrated camera/display operation can also improve eye contact in mobile devices.

Further, the integrated combination of a tactile user interface (touch screen) capability and a proximate (hand image) gesture user interface capability can provide a more flexible, sophisticated, and higher accuracy user interface.

Either of these arrangements allows for a common processor to be used for display, camera, proximate gesture user interface, and tactile user interface (touch screen) functionalities. The result dramatically decreases the component count and system complexity for contemporary and future mobile devices such as cellphones, smartphones, PDAs, tablet computers, and other such devices.

System Architecture Advantages and Consolidation Opportunities for Mobile Devices

The arrangements described above allow for a common processor to be used for display and camera functionalities. The result dramatically decreases the component count, system hardware complexity, and inter-chip communications complexity for contemporary and future mobile devices such as cellphones, smartphones, PDAs, tablet computers, and other such devices.

FIG. 41 depicts an exemplary reference arrangement comprised by mobile devices such as cellphones, smartphones, PDAs, tablet computers, and other such devices.

FIG. 42 depicts an exemplary variation of the exemplary reference arrangement of FIG. 41 wherein an LED array replaces the display, camera, and touch sensor and is interfaced by a common processor that replaces associated support hardware. In an embodiment, the common processor is a Graphics Processing Unit (“GPU”) or comprises a GPU architecture.

FIG. 43 depicts an exemplary variation of the exemplary reference arrangement of FIG. 42 wherein the common processor associated with the LED array further executes at least some touch-based user interface software.

FIG. 44 depicts an exemplary variation of the exemplary reference arrangement of FIG. 42 wherein the common processor associated with the LED array further executes all touch-based user interface software.

Advantageous Use of Supplemental Integrated Capacitive Sensors

In an embodiment, a capacitive sensor may be used to supplement the optical tactile sensing capabilities describe thus far. FIG. 45 depicts an exemplary embodiment comprising an LED array preceded by a microoptics vignetting array and a capacitive matrix sensor. FIG. 46 depicts an exemplary embodiment comprising an LED array preceded by a microoptics vignetting array that is physically and electrically configured to also function as a capacitive matrix sensor. This can be accomplished by making at least some portions of the microoptics vignetting array electrically conductive.

CLOSING

While the invention has been described in detail with reference to disclosed embodiments, various modifications within the scope of the invention will be apparent to those of ordinary skill in this technological field. It is to be appreciated that features described with respect to one embodiment typically can be applied to other embodiments.

The invention can be embodied in other specific forms without departing from the spirit or essential characteristics thereof. The present embodiments are therefore to be considered in all respects as illustrative and not restrictive, the scope of the invention being indicated by the appended claims rather than by the foregoing description, and all changes which come within the meaning and range of equivalency of the claims are therefore intended to be embraced therein. Therefore, the invention properly is to be construed with reference to the claims.

Although exemplary embodiments have been provided in detail, it should be understood that various changes, substitutions and alternations could be made thereto without departing from spirit and scope of the disclosed subject matter as defined by the appended claims. Variations described for exemplary embodiments may be realized in any combination desirable for each particular application. Thus particular limitations, and/or embodiment enhancements described herein, which may have particular advantages to a particular application, need not be used for all applications. Also, not all limitations need be implemented in methods, systems, and/or apparatuses including one or more concepts described with relation to the provided exemplary embodiments. 

1. A system for implementing the function of a visual display, light field sensor, and a user interface for operated by a user hand, the system comprising: A processor, the processor having an electrical interface and for executing at least one software algorithm; A transparent OLED array comprising at least a plurality of OLEDs, the OLED array configured to be in communication with the electrical interface of the processor; An optical vignetting arrangement for providing a plurality of distinct vignets of an incoming light field, and A light emitting arrangement associated with the transparent OLED array, the light emitting arrangement for providing a visual display; Wherein each distinct vignet of the incoming light field is directed to an associated individual OLED from the plurality of OLEDs; Wherein each of the individual OLED performs a light detection function at least for an interval of time, the light detection function comprising a photoelectric effect that is communicated to the processor via the electrical interface of the processor; and Wherein the photoelectric effect that is communicated to the processor is used to obtain light field measurement information responsive to the incoming light field.
 2. The system of claim 1 wherein the light emitting arrangement is provided by OLEDs in the transparent OLED array.
 3. The system of claim 1 wherein the light emitting arrangement is provided by another OLED array.
 4. The system of claim 1 wherein the light emitting arrangement is provided by an LCD.
 5. The system of claim 1 wherein the light field measurement information is used to create light field sensor output information.
 6. The system of claim 5 wherein the light field sensor output information is used to implement a proximity hand gesture user interface.
 7. The system of claim 5 wherein light field sensor output information is used to implement a tactile user interface.
 8. The system of claim 1 wherein the transparent OLED array is configured to perform light sensing for at least an interval of time. 